An example developer tools system provided by a messaging system includes a software development kit (SKD) engagement monitor that permits capturing app open events in third party resources (e.g., third party apps) that use the developer tools system. The SKD engagement monitor is configured to operate in a manner that preserves privacy of the third party developers and avoids conveying to the messaging system backend environment personally identifiable information (PII) about the third party resource usage.

An example developer tools system provided by a messaging system includes a software development kit (SKD) engagement monitor that permits capturing app open events in third party resources (e.g., third party apps) that use the developer tools system. The SKD engagement monitor is configured to operate in a manner that preserves privacy of the third party developers and avoids conveying to the messaging system backend environment personally identifiable information (PII) about the third party resource usage.

Techniques are described for generating HLSD for a textual format source code, which, when rendered, causes a display of visual content. The rendering of the source code generates a tree hierarchy of visual source elements, which logically is possible to map to any graph tree. In an embodiment, visual source elements of the source code are classified to higher-level semantic data (HLSD) labels based on their property(s) and/or the property(s) of neighbor visual source element(s) in the tree hierarchy (context). The HLSD labels indicate the type of HLSD widget mapped to the visual source elements. Techniques further include determining features and a layout arrangement for HLSD widgets and generating a template thereof for the visual content.

In a method of group control and management among electronic devices, wherein the electronic devices is in communication with a control device, a projectable space instance is provided for the control device to create a workspace, wherein a control and management tool and a plurality of unified tools for driving respective electronic devices are selectively added to the projectable space instance. The projectable space instance is then parsed with a projector by the control device to automatically generate a projected workspace corresponding to the workspace to be created via the projectable space instance. The control and management tool realizes at least one status information of at least a first one of the electronic devices by way of the unified tools, and controls at least a second one of the electronic devices to execute at least one task corresponding to the at least one status information.

In a method of group control and management among electronic devices, wherein the electronic devices is in communication with a control device, a projectable space instance is provided for the control device to create a workspace, wherein a control and management tool and a plurality of unified tools for driving respective electronic devices are selectively added to the projectable space instance. The projectable space instance is then parsed with a projector by the control device to automatically generate a projected workspace corresponding to the workspace to be created via the projectable space instance. The control and management tool realizes at least one status information of at least a first one of the electronic devices by way of the unified tools, and controls at least a second one of the electronic devices to execute at least one task corresponding to the at least one status information.

A software robot is designed to carry out an activity (e.g., a mouse click, a text input, etc.) on a target element (e.g., a button, an input field, etc.) of a user interface. The robot's code specification is configured to include an on-screen image of the target element and a text displayed by the target element. The robot is configured to automatically identify the target element at runtime according to an element ID specified in the source-code of the user interface, and when such identification fails, to identify the target element according to the text and image stored in the robot's code.

A method and system for generating engineering diagrams in an engineering system includes receiving specification of one or more physical components. Further, the method includes obtaining, from a data source, a first engineering diagram representing a portion of a technical installation. The method further includes identifying a deviation in the one or more physical components, physical connections and the parameter values in the first engineering diagram based on the specification of the one or more physical components. Furthermore, the method includes generating an engineering diagram analytics model for the first engineering diagram based on the identified deviation in the one or more physical components, the physical connections and the parameter values in the first engineering diagram. Also, the method includes generating a second engineering diagram representing the upgraded portion of the technical installation based on the generated engineering diagram analytics model.

A method and system for generating engineering diagrams in an engineering system includes receiving specification of one or more physical components. Further, the method includes obtaining, from a data source, a first engineering diagram representing a portion of a technical installation. The method further includes identifying a deviation in the one or more physical components, physical connections and the parameter values in the first engineering diagram based on the specification of the one or more physical components. Furthermore, the method includes generating an engineering diagram analytics model for the first engineering diagram based on the identified deviation in the one or more physical components, the physical connections and the parameter values in the first engineering diagram. Also, the method includes generating a second engineering diagram representing the upgraded portion of the technical installation based on the generated engineering diagram analytics model.

Performing usage-based software library decomposition is disclosed herein. In some examples, a processor device generates a first library graph representing a first software library including multiple functions. The first library graph comprises a plurality of nodes that each correspond to a function of the first software library. The processor device identifies a function within the first software library (“invoked function”) that is directly invoked by an application that depends on the first software library, then generates a call graph including nodes within the first library graph (“dependency nodes”) corresponding to either the invoked function or another function invoked by the invoked function during application execution. Using the call graph, the processor device generates a second software library including only functions of the first software library corresponding to dependency nodes of the call graph.

A solution to the problems caused by manual computer programming is provided. A Pseudo-code Design Platform (PDP) reduces the amount of technical skill, length of time, and cost required to create and maintain computer applications. The Pseudo-code Compiler performs as a true Integrated Design Environment. All of the software development steps are performed automatically 100% of the time, within the Pseudo-code Design Platform, just in the opposite order of the conventional process.